KR101278838B1 - Apparatus for inserting cooling fin - Google Patents

Abstract

PURPOSE: A device for inserting a cooling pin is provided to improve the productivity and to reduce the fault rate by controlling the height of a guide rod according to the form, the size, a material, and a condition of the cooling pin. CONSTITUTION: A device (10) for inserting a cooling pin comprises a housing (100), a traction body (200), an insertion guiding member (300), and a locking device. The locking device includes a driving shaft, a pneumatic cylinder, a connecting member, and a hook. The pneumatic cylinder includes a piston rod. The connecting member connects the piston rod and changes the linear movement of the piston rod into the rotating movement of the driving shaft. The hook is connected to the driving shaft and controls the discharge of the cooling pin according to the rotation of the driving shaft.

Description

Cooling Fin Inserting Equipment {APPARATUS FOR INSERTING COOLING FIN}

The following description relates to a cooling fin insertion device.

In heat exchangers used in equipment such as refrigerators that allow the storage to be stored for a long time by keeping the temperature lower than the surroundings, a plurality of cooling fins may be coupled to the surface of the refrigerant pipe at regular intervals for heat exchange between the refrigerant and the air. do. To this end, the cooling fins may be manually coupled to the refrigerant pipes and then the refrigerant pipes may be expanded, or the cooling fins may be first inserted into the trays, and then the trays may be matched to the refrigerant pipes to collectively cool the fins. You can also combine

According to one embodiment of the cooling fin inserting apparatus for inserting the cooling fins into the insertion groove formed in the tray, the cooling fin inserting device is a housing in which the cooling fins are accommodated and the opening is formed on one side, to move the housing along the tray Traction body, the cooling fin may include an insertion guide member for pressing the cooling pin in place when the cooling pin is discharged through the opening is inserted into the insertion groove of the tray. At this time, the insertion guide member may be a bar shape of an elastic material having a predetermined length.

According to another embodiment, the cooling fin insertion device may further include at least one guide rod positioned inside the housing and guiding the cooling fins. At this time, the cooling pin inserting device is a guide to which the top of the guide rod is inserted and fixed, the shape surrounding the side and the rear of the upper end of the housing, a through slit is formed on the rear, the mounting can be mounted on the side It may further include a fixing cover in which a groove is formed and a coupling means inserted into the through slit at the rear of the fixing cover to couple the fixing cover to the housing.

According to another embodiment, the cooling fin insertion apparatus may further include a support member for supporting a load of at least some of the cooling fins accommodated in the housing.

According to another embodiment, the cooling fin insertion device may be positioned adjacent to the opening, and may further include a locking protrusion for supporting one side of the cooling fin to rotate the cooling fin when the cooling fin is discharged. At this time, the locking projection may be configured to be movable up and down to adjust the angle at which the cooling fin is rotated.

According to another embodiment, the cooling fin insertion device may further include a locking device positioned adjacent to the opening and controlling whether the cooling fin is discharged. At this time, the locking device may include a drive shaft connected to the housing, a drive motor for rotating the drive shaft, coupled to the drive shaft to control the discharge of the cooling fins in accordance with the rotation of the drive shaft. In addition, a drive shaft connected to the housing, a pneumatic cylinder including a piston rod, a connecting member for connecting the drive shaft and the piston rod and converts the linear movement of the piston rod into a rotational movement of the drive shaft, coupled to the drive shaft to rotate the drive shaft According to the modification of the locking device including a hook for controlling the discharge of the cooling fins is possible.

According to yet another embodiment, the cooling fin insertion device may further include a rotating means for rotating the housing. At this time, the rotating means may include a pneumatic cylinder including a piston rod, a connecting member connecting the piston rod and the housing and converting the linear movement of the piston rod into the rotational movement of the housing,

The housing may be hinged to the towing member to rotate about the hinge coupling.

According to yet another embodiment, the housing may comprise a wheel driven on the tray surface, an elastic body connected to the wheel to adapt to the tray surface. According to another embodiment, the cooling fin insertion device may further include a sensor for measuring the number of cooling fins discharged.

According to another embodiment, the cooling fin insertion device may further include a sensor for measuring the moving distance of the housing.

1 is a perspective view showing an embodiment of a cooling fin insertion device.
Figure 2 is a perspective view showing another embodiment of the cooling fin insertion device.
3 to 5 is a side view showing a state in which the cooling fin is inserted and the locking device is operating.
6A and 6B are side and front views showing a modification of the locking projection.
7 is a front view showing an example of the support member.
8 and 9 are side views illustrating an example in which the housing is rotated.
10 is a perspective view illustrating an upper end of a housing according to another embodiment.

Hereinafter, various embodiments of the cooling fin insertion apparatus will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of the cooling fin insertion device 10. As shown, the cooling fin inserting apparatus 10 is a housing 100, the cooling fin 1 is accommodated and the opening 110 is formed on one side, the retractor for moving the housing 100 along the tray (2) (200) When the cooling fin (1) is discharged from the housing 100 through the opening 110 is inserted into the insertion groove formed in the tray 2, the insertion guide member for pressing the cooling fin (1) in place ( 300).

First, a description of the housing 100, the housing 100 has a shape corresponding to the shape of the cooling fin (1) to accommodate the cooling fin (1) inserted into the tray (2). That is, there is no restriction on the shape as long as it can accommodate the cooling fins 1 used. In the present embodiment, the housing 100 has a hollow portion in which the cooling fins 1 are accommodated, and has a shape of the letter “C” having the front portion bent so that the number of the received cooling fins 1 can be measured from the outside. Have In addition, the cover may be provided to cover the front portion of the housing 100, in this case there is an advantage that can protect the cooling fin (1) from dust of the working environment. The size of the housing 100 may also be adjusted by the user according to the working environment. An opening 110 is formed at a lower end of the housing 100 so that the received cooling fin 1 is discharged through the opening 110 and inserted into the tray 2.

Next, the retractor 200 allows the housing 100 to move along the tray 2. For example, the towing body 200 may include at least one wheel, and the guide rail 3 on which the wheel is driven is provided to move the housing 100 through the cooling fins (2) on the tray 2. 1) can be inserted. In this embodiment, the traction body 200 is coupled to the housing 100 spaced apart, but the present invention is not limited thereto, and if the housing 100 can be moved along the tray 2, the method and / Or there is no limitation on the configuration. In addition, the towing body 200 may be operated manually, or may be automatically provided with a separate device. When manually operated, the handle 270 may be provided.

In addition, the cooling fin insertion device 10 may include an insertion guide member 300, in the present embodiment, the insertion guide member 300 is an opening of the housing 100 through which the cooling fin 1 is discharged. Disposed adjacent to (110). Insertion guide member 300 is to solve the problem that the cooling fin (1) is not completely inserted when inserted into the insertion groove of the tray 2, the cooling fin (1) to some extent inserted into the insertion groove from top to bottom To set it in position. In addition, when the cooling fin (1) is inserted while moving the housing 100 quickly, the pin is repelled against the bottom of the insertion groove and is not placed in position. Press the insertion guide member 300 to position it. Through this, after inserting the cooling fins into the tray with the cooling fin inserting device, it is possible to prevent the economical cost of pressing the cooling fins which are not properly inserted manually, and to increase the moving speed of the housing 100 to increase productivity. Significantly higher If the cooling fin (1) can be pressed from the top to the bottom is not limited. For example, in the present embodiment, a plurality of rod-shaped insertion guide members 300 having a predetermined length are provided, but a thin surface insertion guide member may also be used. In addition, the insertion guide member 300 may be an elastic material. Thus, the cooling fin 1 can be smoothly positioned in accordance with the bending formed by the upper ends of the series of cooling fins 1 depending on the degree of insertion of the cooling fins 1. As the elastic material, plastic, rubber, or the like may be used. When the insertion guide member 300 is planar, a thin FPCB (flexible circuit board) may be used.

It is configured as described above, the cooling fin insertion apparatus 10 accommodates a plurality of cooling fins 1 in the housing 100, and the cooling fins 1 are discharged through the openings 110 by their own weight. The discharged cooling fin 1 is inserted into the insertion groove on the tray 2, and the towing body 200 moves the housing 100 in the longitudinal direction of the tray 2 to uniformly perform the cooling fin insertion operation. To be able. Finally, the cooling fin (1) is inserted and at the same time by pressing the cooling fin (1) in which the insertion guide member 300 is inserted into place.

2 is a perspective view showing another embodiment of the cooling fin insertion device 10. As shown, the cooling fin insertion apparatus 10 may further include at least one guide rod 120 positioned inside the housing 100 and guiding the cooling fin 1. In the present embodiment, two guide rods 120 are provided, and the cooling fins 1 are inserted to penetrate the guide rods 120 so that the guide rods 120 freely fall to their own weight. To guide. Through this, a plurality of cooling fins 1 can be stably lowered. In addition, as shown in Figure 3, the lower end of the guide rod 120 may be curved in the front side. Due to the curved shape toward the front side, the cooling fin 1 may be discharged at a large angle with respect to the tray 2, so that the cooling fin 1 may be more easily inserted into the insertion groove of the tray 2.

In addition, the cooling fin insertion apparatus 10 may further include a support member 140 connected to the housing 100 and supporting a load of at least some of the cooling fins 1 accommodated in the housing 100. . The cooling fin (1) accommodated as shown further includes a support member 140 is separated. Therefore, the load applied to the cooling fin 1 in the lower portion, in particular, the cooling fin 1 discharged through the opening 110 may be distributed to prevent a phenomenon in which two or more cooling fins are inserted into one insertion groove. . The structure of the support member 140 will be described later in detail with reference to FIG. 7.

In addition, the cooling fin insertion apparatus 10 may further include a locking device 150 positioned adjacent to the opening 110 and controlling whether the cooling fin 1 is discharged. Thus, even when the housing 100 is erected close to the vertical, the received cooling fins 1 may be maintained inside the housing 100 without being poured. In this embodiment, the locking device 150 is a drive shaft 151 connected to the housing 100, a pneumatic cylinder 153 including a piston rod 152, the drive shaft 151 and the piston rod 152. The coupling member 154 for converting the linear movement of the piston rod 152 into the rotational movement of the drive shaft 151, coupled to the drive shaft 151, cooling pin (1) in accordance with the rotation of the drive shaft 151 It includes a hook 155 for controlling the discharge of). The operating principle of the locking device 150 of this configuration will be described in detail with reference to FIGS. In addition, although not shown, the locking device 150 is connected to the housing 100, a drive motor for rotating the drive shaft, coupled to the drive shaft to control whether or not the discharge of the cooling fin (1) in accordance with the rotation of the drive shaft. It may be configured to include a hook. According to this, the driving shaft rotates due to the operation of the driving motor, and the hook coupled to the driving shaft also rotates according to the rotation to determine whether the cooling fin 1 is discharged.

3 to 5 is a side view showing a state in which the cooling fin (1) is inserted and the locking device 150 operates. As described above, the locking device 150 may include a pneumatic cylinder 153 including a piston rod 152, a connection member 154, a hook 155, a drive shaft 151. The drive shaft 151 is coupled to the front side of the housing 100 is spaced apart, it is possible to rotate. The connection member 154 connects the drive shaft 151 and the piston rod 152 of the pneumatic cylinder 153 and simultaneously converts the linear movement of the piston rod 152 into a rotational movement to rotate the drive shaft 151. In this embodiment, the connection member 154 has one side fixedly coupled on the drive shaft 151, the end of the piston rod 152 is provided with a slit that can be moved through (ie, long hole shape). The hook 155 is fixedly coupled to the drive shaft 151 to rotate together with the rotation of the drive shaft 151.

3, the piston rod 152 is out of the pneumatic cylinder 153 as shown in FIG. 3, and the end of the piston rod 152 is driven in the slit of the connecting member 154. Located farthest away, the hook 155 is locked to support the cooling fin (1) to be discharged. 4 and 5 show the discharged state, in which the piston rod 152 is pulled into the pneumatic cylinder 153, so that the end of the piston rod 152 is in contact with the drive shaft 1 in the slit of the connecting member 154. Move closer As a result, the connection member 154 rotates clockwise, the drive shaft 151 connected to the connection member 154 also rotates clockwise, and the hook 155 connected to the drive shaft 151 also rotates clockwise to cool the fins. The cooling fins 1 are discharged by releasing the support applied to the (1).

The cooling fin insertion device 10 may further include a locking protrusion 130 to allow the cooling fin 1 to rotate when the cooling fin 1 is discharged. The locking protrusion 130 is positioned adjacent to the opening 110, and rotates by supporting one side of the cooling fin 1 when the cooling fin 1 is discharged. 3 to 5, the locking projection 130 is installed on the front portion of the housing 100 may support the left side of the cooling fin (1) on the side view. If only one side of the cooling fin (1) is supported, the shape and position is not limited. In the present embodiment, the above-described function may be performed even in the shape of a cylindrical rod arranged in a direction parallel to the driving shaft 151 or a locally protruding shape. As such, when the cooling fins 1 are rotated while being discharged, a larger angle may be formed with respect to the insertion grooves of the tray 2, so that the cooling fins 1 may be inserted more easily. In addition, it may be necessary to adjust the discharge angle of the cooling fin (1) in accordance with the material and / or state of the cooling fin (1). That is, a hole is normally formed on the cooling fin 1, and this hole part protrudes slightly compared with the other part. However, the degree of protruding may vary depending on the type of cooling fin 1, and the degree of protruding may not be constant depending on the material and / or state of the cooling fin 1. Therefore, when the cooling fins 1 are discharged with a large angle toward the vertical direction, the insertion is generally performed well, but if the degree of protrusion is not fixed, the problem is that the insertion is not good, and the discharge angle of the cooling fins 1 is increased. Reducing to the horizontal direction, on the contrary, inserts well when the degree of protrusion is not constant. As described above, FIGS. 6A and 6B are provided to explain a modified example of the locking protrusion 130 that can adjust the discharge angle of the cooling fin 1 according to a user's selection. 6A and 6B are side and front views showing a modification of the locking projection. The front view of FIG. 6B is a view seen from the right side based on the side view of FIG. 6A. As shown in Figure 6a, in the present embodiment, the engaging projection 130 is coupled to the front surface of the housing 100, the side is "b" shaped, the projection is formed at the bottom by the projection The cooling fins 1 are supported and rotated. As shown in FIG. 6B, the through protrusion slit 132 having a long hole shape is formed in the locking protrusion 130, and a fixing means 132 such as a bolt is fitted to the through slit 132 to press the housing 100. By fixing the engaging projection 130 to the housing 100, by moving the position of the coupling means 132 in the through slit 132 as necessary to move the locking projection 130 up and down. Can be. If the locking projection 130 is moved upward, the discharge angle (rotation angle) of the cooling fin 1 is relatively increased, and if it is moved downward, the discharge angle of the cooling fin 1 is relatively reduced, so that the user is made of the material of the cooling fin. According to the shape and / or state, the discharge angle can be adjusted accordingly. At this time, it is preferable to prevent the cooling fin 1 from being rotated by the fixing means 132 rather than the protrusion by allowing the lower protrusion of the locking protrusion 130 to protrude more than the fixing means 132 as shown. Do. In addition, unlike shown, it is also possible to modify the insertion means 132 in the opposite direction. That is, the through slit is not formed in the locking projection, but is formed on the front side of the housing and a fixing means such as a screw is inserted into the housing from the outside of the front side of the housing through the through slit. At this time, the fixing means may be engaged with the locking protrusion inside the housing to fix the position of the locking protrusion. Also in this case, the up and down position of the locking projection can be adjusted by manipulating the position in the through slit of the fixing means. Further, if necessary, a method of welding the fixing means to the locking projections is also possible.

Looking at the operation of the cooling fin insertion device 1 configured as described above, as shown in Figure 3 the piston rod 152 comes out of the pneumatic cylinder 153 to maintain a locked state, the cooling fin (1) in the housing 100 ) Is accepted. When the insertion groove is reached, the piston rod 152 is pulled to rotate the hook 155 to release the locking state as shown in FIG. 4, and the cooling fin 1 descends along the guide rod 120 to catch the protrusion 130. ) Is ejected while being rotated with the support of the insert and inserted into the insertion groove. Subsequently, as shown in FIG. 5, the towing member 200 uniformly inserts the cooling fin 1 while moving the housing 100, and at the same time, the insertion guide member 300 presses the cooling fin 1 to be positioned in the insertion groove. Let's do it.

3 to 5, the housing 100 of the cooling fin insertion device 10 includes a wheel 160 driven on the tray surface and an elastic body 165 connected to the wheel 160 to adapt to the tray surface. It can be provided. A wheel 160 driven on the tray surface is provided to support the load of the housing 100 including the cooling fins 1 and to move more stably. In addition, an elastic body 165 such as a spring may be connected to the wheel 160 to adapt to the surface of the tray 2. That is, when it is necessary to insert the cooling fin (1) in the tray (2) having a raised portion as necessary, the wheel 160 can be stably operated by adapting to the surface due to such an elastic body (165) In the case of unexpected unevenness and / or protrusion on the tray 2, it is adapted to this and enables stable driving.

7 is a front view illustrating an example of the support member 140. As described above, the cooling fin insertion device 10 further includes a support member 140 connected to the housing 100 and supporting a load of at least some of the cooling fins 1 accommodated in the housing 100. By distributing the load applied to the cooling fins 1, two or more cooling fins may not be inserted into one insertion groove. In this embodiment, the support member 140 is implemented in the form of a bolt that is fixed through one side of the housing 100, so that the portion penetrated into the housing 100 does not descend by supporting the cooling fin (1). do. The configuration of the support member for performing such a function may vary. For example, it is composed of a rod-like or planar body penetrating both sides of the housing 100 to prevent the falling of the cooling fin (1), if necessary can be removed by lowering the cooling fin (1).

8 and 9 are side views of the cooling fin insertion device 10 showing an example in which the housing 100 is rotated. As described above, the cooling fin 1 can be easily supplied to the housing 100 before the operation by rotating the housing 100, and the support member 140 is released during the operation to cool the housing 100. The pin 1 can be lowered, and the repair and repair of the cooling fin insertion device 10 including the detachable attachment of the guide rod 120 can be facilitated. The rotating means 250 for rotating the housing 100 connects the pneumatic cylinder 253 including the piston rod 252, the piston rod 252 and the housing 100, and performs a linear movement of the piston rod 252. It may include a connecting member 254 for converting the rotational movement of the housing 100, the housing 100 can be rotated about the hinge coupling 251 by the hinge coupling 251 with the retractor 200 have. More specifically, FIG. 7 illustrates a state in which the piston rod 252 is pulled into the cylinder 253 and the housing 100 is erected. FIG. 100 shows the state lying down. At the same time as the piston rod 252 comes out, the connecting member 254 rotates in a clockwise direction, and accordingly, the housing is coupled to the connecting member 254 by a hinge coupling 251 rotatably to the traction body 200 ( 100) can also rotate clockwise. Such rotation means 250 may be implemented in various ways. For example, a drive shaft connected to the housing and a drive motor for rotating the drive shaft may be provided to rotate the housing according to the rotation of the drive shaft.

Here, the towing body 200 may include a handle portion 270. The handle 270 may be used to move the retractor 200 in a manual manner, and may serve to support the load of the housing when the housing 100 is rotated and laid down.

10 is a perspective view illustrating the upper end of the housing 100. According to another embodiment, the cooling pin inserting device 10 is a shape that surrounds the side and rear of the upper end of the guide rod 120, the upper end of the guide rod 120 is fixed and inserted, the housing 100, the rear The through slit 122 is formed in the fixing cover 125 is formed in the mounting groove 124 on which the holder can be mounted on the side, the fixing cover 125 is inserted into the through slit 122 at the rear of the fixing cover 125 It may further include a coupling means 123 for coupling the fixing cover 125 to the housing 100. In the above embodiments, there was no guide or the guide rod was inserted into the guide so that the guide was mounted or coupled directly to the housing. However, in this embodiment, the fixing cover 125 having a shape surrounding the side and rear surfaces of the housing 100 is provided. To surround the housing 100, and a through slit 122 is formed at a rear surface of the fixing cover 125 so that a coupling means 123 such as a bolt or a screw is inserted into the through slit 122 so that the housing 100 can be inserted into the housing 100. By pressing or screwing the fixing cover 125 is coupled to the housing 100. In addition, a mounting groove 124 is formed on the side of the fixing cover 125 so that the fixing rod 121 is mounted on the mounting groove 124. On the other hand, the guide rod 120 is coupled to the lower portion of the holder 121. As such, the guide rod 120 is coupled to the fixing rod 121, the fixing rod 121 is mounted on the fixing cover 125, the fixing cover 125 is coupled to the rear of the housing 100, fixing cover 125 By moving the up and down), ultimately, the guide rod 120 may be moved up and down. That is, if necessary, after releasing the coupling means 123 to separate the fixing cover 125 from the housing 100, the fixing cover 125 is disposed again at a desired position, and the housing 100 is coupled to the coupling means 123. When combined with) will change the position of the guide rod 120. When the guide rod 120 is lowered to approach the tray, the cooling fin 1 is generally inserted in a constant and deep well, but the cooling fin 1 is dependent on the material and / or state of the cooling fin 1. Deformation or breakage may occur, such as bending. In this case, the height of the guide rod 120 may be slightly raised to prevent deformation or damage as described above. Thus, it is necessary to adjust the height of the guide rod 120 in detail according to the shape, size, material, or state of the cooling fin (1), through which it is possible to increase the productivity by lowering the defective rate.

Although not shown, the cooling fin insertion device 10 may further include a sensor. For example, a sensor for measuring the number of cooling fins 1 disposed to be disposed adjacent to the opening 110 may be provided to insert a predetermined number of cooling fins 1. In addition, it may be disposed adjacent to the traction body 200 or the wheel 160 to measure the moving distance of the housing 100 to insert the cooling fin 1 by a predetermined distance.

The contents described above are merely embodiments of the present invention, and the scope of the present invention is not limited to the described embodiments, but should be understood by those skilled in the art within the spirit and scope of the present invention. Various changes, modifications, or substitutions of will be possible and such embodiments are to be regarded as within the scope of the present invention.

1: cooling fin 2: tray
3: guide rail 10: cooling pin insertion device
100 housing 110 opening
120: guide rod 130: jamming projection
140: support member 150: locking device
160: wheel 200: towing
300: insertion guide member

Claims (15)

In the cooling pin insertion device for inserting the cooling fins into the insertion groove formed in the tray,
A housing accommodating the cooling fins and having an opening formed at one side thereof;
A towing body for moving the housing along the tray;
An insertion guide member configured to press and hold the cooling fin when the cooling fin is discharged through the opening to be inserted into the insertion groove; And
A locking device positioned adjacent to the opening and controlling the discharge of the cooling fins;
Lt; / RTI >
The locking device comprises:
A drive shaft connected to the housing;
A pneumatic cylinder comprising a piston rod;
A connecting member connecting the drive shaft and the piston rod and converting a linear movement of the piston rod into a rotational movement of the drive shaft; And
A hook coupled to the drive shaft to control whether the cooling fin is discharged according to the rotation of the drive shaft;
Cooling pin insertion device comprising a. The method of claim 1,
The insertion guide member is a cooling pin insertion device having a rod shape of an elastic material having a predetermined length. The method of claim 1,
Located inside the housing, the cooling fin insertion device further comprises at least one guide rod for guiding the cooling fins. The method of claim 3,
Fixing rod is fixed to the top of the guide rod is inserted;
A fixing cover having a shape surrounding the top and side surfaces of the housing, a through slit formed at a rear side thereof, and a mounting groove formed at a side thereof to allow the fixing stand to be mounted; And
A coupling means inserted into the through slit at the rear of the fixing cover to couple the fixing cover to the housing;
Cooling pin insertion device further comprising. The method of claim 1,
Positioned adjacent to the opening, and further comprising a locking projection for supporting the side of the cooling fin to rotate the cooling fin when the cooling fin is discharged. The method of claim 5,
The locking projection is configured to be moved up and down to adjust the angle of the cooling fin is rotated cooling pin insertion device. The method of claim 1,
And a support member connected to the housing and supporting a load of at least some of the cooling fins accommodated in the housing. delete delete delete The method of claim 1,
Cooling pin insertion device further comprises a rotating means for rotating the housing. The method of claim 11,
The rotating means
A pneumatic cylinder comprising a piston rod;
A connecting member connecting the piston rod and the housing and converting a linear movement of the piston rod into a rotational movement of the housing;
Lt; / RTI >
The housing is hinged to the traction body and the cooling fin insertion device that rotates around the hinge coupling. The method of claim 1,
The housing
A wheel driven on the tray surface; And
An elastic body connected to the wheel to adapt to the tray surface;
Cooling pin insertion device having a. The method of claim 1,
Cooling pin insertion device further comprising a sensor for measuring the number of the discharged cooling fins. The method of claim 1,
Cooling pin insertion device further comprises a sensor for measuring the moving distance of the housing.

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